DE2140707C3 - Circuit arrangement for program-controlled fenunelde, in particular telephone ventilation systems - Google Patents

Description

55

The invention relates to a circuit arrangement for program-controlled Fernmclde-, in particular Fernsprcchvcrmittlungsanlagen, with several rewritable slow memories, input and output units connected to these slow memories, with several synchronously working central control units for active and remote operation, each of these central control units independent of one another Eimnings- i.id / uisuiingseiiiheilen belonging to the own group to be controlled in which I: ii: c is. at least ··, two part ·, for nktivui HeIrieb, partly liir t ⁷ .r ^ al / 'hclrii ·!' v.tmeselicnen. the central control units shared wiisdeinschreibbarenu short-term memories, each of the input and output units causes an information transfer between the slow memories and the short-term memories based on a control of the central control unit, and the central control unit effects processing of the data read out from the short-term memories.

Such systems have been popular lately both in terms of the amount of data to be processed by them as well as the quality of the way they work, has been significantly further developed. You still need a hybrid communication system that enables the sending and receiving of telephone connection and other data allowed. A system controlled by a memory program appears particularly suitable here. A Such a system includes peripheral equipment that depends on the number of participants or the (Trunk) connecting lines a number of communication paths can form memory problems for Storage of scrvice programs, storage devices for storing data in proportion to the Number of subscribers and control devices with a call processing capacity «that of the total traffic is proportional.

When the number of participants decreases or when in proportion to the number of participants flourish Services are requested, generally the cost of storage facilities for the program, which is not proportional to the number of participants or the total traffic, is considerable. In addition, the reliability of such takes away Systems with their complexity and overdevelopment.

The object on which the invention is based is to create a memory program that can be controlled Circuit arrangement for telecommunication systems, which avoids these disadvantages and a cheap and reliable operation of telecommunications systems in small Dimensions permitted.

The object on which the invention is based is solved by the fact that only a small number, with a few exceptions, actively working fast short-term / long-term storage, those with a double, shared but independently working substitute short-term memory are connected, and one rumble accordingly: number of doubly led, slow storage as well as double-run central control units is provided that each of the central control units a register for recording the installation number of one of the high-speed short-term memories contains, the content of the slow memory duieh a short-term memory on this and vice versa the content a? Short-term storage on the slow Memory with the help of the register for the logic addresses used for the input and output units can be transferred and if one part or several different parts fail (Short-term storage, replacement short-term storage, slow storage or central control unit) his or her Task is carried out by another part that when storing a facility number of a short-term memory except for the substitute short-term memory, in the register and when an access from the central control unit to the short-term memory, the facility number of which is stored in the register, which Access to the rate cure / time memory takes place so that icde ZentriilslciK'reinhrit only: m / II, · <-l <-r,.; "" "" "

Group of associated input-output units Emits command information, and that each input and output unit sends response signals and information can only be fed back to the two central control units.

The invention seeks to create an economic one Arrangement of high reliability, which remains arbi.; .., f: ihig even if an essential error occurs in a liner component. Relatively cheap and slow storage devices can be used be such as magnetic drum, magnetic phitten or delay lines to the same function as mi! to achieve fast storage devices can. The access time for these economical, slow storage devices is reduced, so that the system can handle more traffic can. By connecting double, slow storage devices and duplicate central control devices will improve the reliability of the control maintained.

A further increase in profitability is achieved by reducing the number of faster, temporary storage by providing a shared standby facility that allows the system allowed to work in high-speed mode by the Iibalt of the slow memory is transferred to the fast, temporary memory

A detector to record calling subscribers is the time span that the central Control device for internal processing can use increased.

In the arrangement according to the invention also, less frequent programs and data in the more economical, slower storage devices subordinated and in the fast, temporary storage facility! η transferred and used from these. There are less complex devices, such as about magnetic drums or the like., available twice and used as a slow memory, while the fast, temporary storage facilities have a common standby facility. Through this the central control units can switch off one of the double subsystems in the event of errors, while the performance of the entire system is maintained unchanged.

The lowest possible access time of the slow storage devices can be achieved, so that the first tangible duplicate information of the slow storage devices can be triggered.

The system can operate without modification of the service program by changing the fast, temporary storage facilities to accommodate a program for switching the service programs, which are normally in the slow Storage devices are stored in the fast, temporary storage devices used will.

To explain the invention in more detail, the exemplary embodiment shown in the drawing is described. In it shows

1 shows a block diagram of the system according to the invention,

2.1 a circuit diagram for the redundancy device of the central process computer of the system in normal operation,

2.2 shows a circuit diagram of the process computer according to FIG. 1. if there is an error either in the central control unit CC or in the magnetic drum unit MDU of the system,

2.3 shows a circuit diagram of the process computer according to FIG. 2.1 when one of the temporary storage devices is faulty,

3 shows a circuit diagram for the redundancy device the peripheral equipment of the system,

4 shows a block diagram of the central control unit CC of the system,

FIG. 5 is a block diagram of the Arithmctikc'nhei · ίο ARITH of the unit according to FIG. 4,

6 shows a block diagram of the access control of a temporary storage unit TM of the system. 7 shows a schematic circuit diagram of an internal memory TM,

Fig. 8 is a block diagram for the arrangement of the M: \ - gncitrommeln in the system,

Fig. 9 is a scheme of the "üfdetcktors CO iL., Systems,

10 is a block diagram of the call routing control VPC of the system,

Fig. II a Schaltschcma to represent the Control of a call from a subscriber,

FIG. 12 is a circuit diagram of the program process computer of the system in normal operation,
5 Fig. 13 shows the pulse flow of the program process clock in normal operation,

Fig. I-i a circuit diagram of the process computer in Substitute operation,

Fig. 15 shows the pulse waveform of the program process computer in replacement operation,

16 shows a representation of a magnetic drum with the accommodation of the programs,

17 shows a representation of a preferred embodiment of the magnetic drum,
18 shows the pulse waveform during operation of the magnetic drum units and

Figure 19 is a block diagram showing part of the system including the magnetic drum units.

In the further description of a preferred embodiment of the electronic telecommunications system explained under the following headings:

1. General overview of the system (Fig. 1, 2 and 3),

2. the central control unit CC (Fig. 4),
2.1 Execution of the cinci instruction (Fig. 5).

2.2 data adaptation (Fig. 5),

2.3 CC adaptation control (Fig. 5),

2.4 interruption (Fig. 5),

2.5 Effect in an emergency (Fig. 5),
2. TM access control (Fig. 6),

2.7 peripheral control (Fig. 6),
2.H TAi switch control (Fig. 7).
2.9 Control of the magnetic drum duct device (Fig. 8).
2.10 magnetic drum control (Fig. 8),

2.1 1 How the temporary memory works (Fig. 6).

3. Speech route control and call detector,

3.1 Speech route control (Fig. 10),

3.2 Call detector (Fig. 9),

4. Overview of a voice connection (Fig. 11).

5. How the program control works,

5.1 Explanation of the programs,

5.2 Accommodation of the program and data in the memory TM,

5.3 Operating modes of program processing (Fig. 5, 12.13, 14, 15 and 16),

6. Magnetic drum unit (Figs. 17, 18 and 19).

7. Additional remarks.

I. General overview

Figure H shows a block diagram of an embodiment the founding arrangement. The symbols in or on the blocks place the respective device or Unity and the lines between the blockers mark the forwarding of the lint.ti or control signals.

In Fig. 1 SUBl ... SUBS rKe designates individual subscribers and TRKl ... TKRM, TRKl ... TRKN the connecting lines. The subscribers SUB1 ... SUBS are to a switching unit LLS in a Si-h; \ l! Gcstell [SWF) and the connection lines IRKl UMV. are to a switching unit TLS in a switch frame (SWF) via the connecting line circuits TRKCKT in a Vcrbindungsleiliincseestell ( TRKF) vi'rhiinHi'n Dir Sch-tl'cinhcit'-! ^1st /./..V and TLS are sehaltwcrke, consisting of., He levels of S ν Κ mechanically engaging cross!.; ^ .. !! switches. The switch rack (SWF) further comprises a call detector unit CD with connections to each subscriber line in the trunk switching unit LLS. The detector unit CD is used to detect the individual calling subscribers SUB1 ... SUBS and forms a code therefrom. The switching state of the trunk circuits TRKCKT is detected by an interrogation unit SCN .

The block SPCF in the middle of the drawing, marked with a dashed line, is a peripheral control unit.

A central control unit CC and a distribution unit SRD are duplicated, which is indicated by a suffix 0 and 1, respectively. If these double units are mentioned without a suffix, then both are meant. This also applies to the other following units.

The program-controlled output or input instruction, address information or the like arrives at the distribution unit SRD in the peripheral control frame (SPCF).

The distribution unit SRD distributes the instruction signals and address information to the devices of the system and receives response signals from them. The lines between the blocks of the peripheral control unit (SPCF) indicate the transmission paths for this information. The main entrance to the frame (SPCF) comes from the interrogation unit SCN, which generates a binary-coded output signal, depending on whether the current on the input line and a marked address exceeds a threshold or not. In this exemplary embodiment, the interrogation unit SCN supplies outputs from each of the 16 interrogation points in accordance with 0 to 256 binary addresses.

The query driver unit SCNDV, duplicated according to suffix 0 and 1, controls a sensor in the query unit SCN. The pulse or waveform is restored by a directional amplifier in the interrogation unit SCN, whereupon the signal is sent to the distribution unit SRD . Each of the double units SCND V is connected to the interrogation unit 5CN via a relay RYA . The remaining units of the frame (SPCF) are also duplicated, but not switched, and the outputs of the two duplicate subsystems go to the corresponding central control unit CC ₀ or CC ₁ . The frame (SPCF) has a maintenance interrogation unit MSCN, duplicated according to suffix 0 and 1. The unit MSCN interrogates each of the 16 interrogation points in response to binary-coded address information with four bits. The frame (SPCF ¹ , also has a switch control unit SC , a relay control unit RC and a signal distribution unit SD. The switch control unit SC and the relay control unit RC are also duplicated. The switch control unit SC feeds certain horizontal and vertical coils or windings of the crossbar switches for selection a switch according to the given address information. The selected switch is opened or closed as desired. Normally, the switch control unit 5C ₀ controls the switch unit LLS and the switch control unit 5C controls the switch unit TLS. However, the unit SC _n karsü controls the switch unit TLS and the unit 5C ₁ can control the switching unit LLS when a relay RYB or RYC is operated.

^ao This function is referred to below as the switching function RYBIC.

The ST-SC unit is reserve equipment for large capacity operations. The unit ST-SC controls the switching unit LLS or the

»5 switching unit TLS via a relay RYD or RYE (hereinafter referred to as standby function n + \) ).

The trunk circuits TRKCKT have several modes such as loop.

open on lines or the like. The operating mode is determined in detail by the switching status of a group of magnetic relays. The relay control unit ÄC controls these relays and supplies impulses for actuating or releasing a relay. Each of the relay control units RC ₀ , RC _x is selected by a relay RYC.

The trunk circuits TRKCKT contain service facilities, such as a touch dial receiver, a multi-frequency transmitter, a dial pulse transmitter, etc. The pattern of the multi-frequency pulses from the transmitter or the continuation and interruption of the dial pulse from the transmitter is controlled by a signal distribution unit SD . The signal distribution unit SD consists of a group of flip-flop circuits which are set or reset by a binary address. The output signal of each flip-flop circuit controls the relay of the service action sender.

The unit SD is not duplicated, however

5 »designed so that it has access from each of the duplicate central control units CC ₀ , CC ₁ . When the power source for the unit SD is switched off, the other part of the unit SD remains operational.

A typewriter control unit 7 "PC, also double, can be actuated by keypad instructions, by reading a tape or the like. In Fig. 1, a typewriter 7YPmJt is connected to each unit TPC ₀ , TPC ₁ , each typewriter 7ΎΡ being in a separate maintenance center.

The block CPF at the bottom of FIG. 1, indicated by dashed lines, is a central process computer frame and is used to store the program control data. In this embodiment, the Gesieii (CFF) has one

fast, temporary storage, collectively referred to as TM . The memory TM of the embodiment shows four active devices TM ₀ to TM- and one standby device ST-TM. All of these

Devices are constructed in the same way, essentially a core memory for reading in and reading out 4096 binary words, each consisting of 17 bits, ie of 16 bits plus one parity bit. Each device TAf ₀ to TM ₁ is assigned a fixed address of a higher order and the entire memory has consecutive addresses from 0 to (4906 X 5-1). A variable higher-order address is given to the device ST-TM so that it can take the place of any of the four other active devices TzVf ₀ to TM _} . The memory TM contains data that are generated by the central control units CC ₀ . CC _{1 can be} read, executed or modified. These units CC _n , CC ₁ work synchronously and execute an instruction after checking the coincidence of the work with the internal adapter circuit. If one of the units CC _n , CC _{1 works} incorrectly, one unit can be switched off so that only the other unit works. The units CL ₀ . CC ₁ can also be controlled manually by a test unit CNS , which is also available in duplicate.

A double magnetic drum unit zVfDt / is connected to a unit CC ₀ , CC _x via the magnetic drum channel device MDCH ₀ , MDCH ₁ . The magnetic drum units MDU ₀ , MDU _x record the same data, but the magnetic drum channel devices MDCH _n , MDCH _{x are} not synchronized, so that one of the double units MDU ₀ , MDU _{x is identified} by the data for reading and the content of the units MDU ₀ , MDU _{1 is the} same.

A block MISCF in the upper right part of FIG. 1 consists of various test and additional circuits. The block ( MISCF) is not essential to the invention and will not be described in detail.

The aforementioned doubling of the various units enables, as will now be described, one advantageous redundancy facility.

According to a basic rule of the system, data that are less frequently used are stored in the drum unit MDU . When these data are required, they are directed to a specific area of the temporary memory TM , hereinafter referred to as the cover area, and then processed. Frequently used data and a program for controlling the data transfer from the unit MDU are permanently stored in the memory TM. In the system according to the invention, the entire memory thus forms a hierarchical construction from a relatively expensive one. fast storage TM and a more economical, slower storage MDU. In comparison with a conventional memory with only fast, high-capacity memories, the storage system performs very favorably in terms of operation and costs.

A further development of the system according to the invention is the substitute mode of operation, which is achieved by duplicating the magnetic drum units MDU and creating a standby device ST-TM of the memory TM .

Fig. 2.1 shows in a circuit diagram the redundancy state of the system in normal operation. In Fig. 2. 1, the central control unit CC _n is active and the central control unit CC _x passively. In this case, in the temporary per'iuuenl Bereilsehaftsspeichercinri Pla-ST-IM-a Hingangs AtiMiangs Verarbeiluimsproliiamin! '. I-speulu-rl in ilen active lemporären Save' nrichtungen TM ₀ to TM _1, the frequently required data are stored. The devices TzVf _n to TM have two coverage areas, of which in the normal state one coverage area is used to forward the internal processing program from the magnetic drum unit MDU ₀ or MDU _x and the other coverage area is not used. The internal processing program is turned off

»O one of the units MDU ₀ , MDU _{x is} read out and the data is stored in both units MDU ₀ . MDU _x entered. Should an error occur in one of the magnetic drum units MDU, the magnetic drum channel device MDCH, the central control unit CC or in one of their combinations, the system switches to the operating mode shown in FIG. 2.2. In this state, the operation is the same as the normal operation except that data is only input to one of the units MDU which is used for reading out the internal work program.

It is now assumed that one of the active, temporary memories TM ₀ to TAi _{3 has} an error. In this case, the system works in one state

^J 5 according to FIG. 2.3 and the common, temporary standby or reserve storage device ST-TM takes the place of the faulty storage device, e.g. B. TM ₀ . In this case, the input and output processing program that is stored in the device ST-TM can no longer be achieved. The input and output processing program is placed in the second coverage area of the device TM ₁ to TM ₃ , which has not previously been used and is processed therefrom. The input and output processing program is selected so that another program can be switched off in 10 milliseconds each, which results in a cycle of 200 milliseconds, for example. In this case, the control unit CC _{0 is} active and the magnetic drum unit MDU _x sends its internal processing program to the first overlap area in one of the temporary storage devices, as the state according to FIG. 2.1 shows. As mentioned above, the unit MDU _x transmits the input and output processing

gram to the second coverage area in one of the storage devices TM. To indicate this clearly and to show that the unit CC _x itself does not identify the address of a memory device TM , a chain line is used in FIG. 2.3. In this state according to FIG. 2.3, the processing capacity of the system is slightly smaller compared to the state according to FIG. 2.1. In the preceding description it was assumed that the temporary standby device ST-TM is active during normal operation. However, it is also possible to modify the system so that the ST-TM enclosure is a complete reserve or standby measure and is not normally used. In this case, the

^s ° device ST-TM simply replace another, temporary storage device TM that is defective.

It follows from the foregoing that the system according to the invention also works when in one of the units CC. MDCH, MDU or TM you

⁶ S ί ^ n! He occurs. Reach! this is achieved through the combination of a double auxiliary storage tank with a large capacity and an external storage tank for Krsat / hi H i> 1-

Hg λ / i-iiil die KediiiHl.iii / iiiaÜiiahHK · i nr Aw | κπ-

phercn devices of the system, where the thick lines indicate the flow of the active control signals and the line lines the auxiliary paths. As can be clearly seen, at least two paths are provided for each peripheral device and the signal receiver and distribution unit SRD can be viewed as part of the central control unit CC of the configuration shown.

2. The central control unit CC

An embodiment of the central control unit CC is shown in FIG. 4, with dashed lines for connecting the components indicating control paths and solid lines indicating paths for the flow of data. It should be mentioned that two units CC _n and CC _{1 are} provided. Each unit consists of an arithmetic controller ACTL, an arithmetic device ARITH, a system controller SCTL, a peripheral controller PCTL, a clock generator CLK, an emergency device EMA and a manual »» test field CNS. The probability that errors will occur in the EMA emergency device itself is low, so that this device is common to the two units CC ₀ , CC ₁ . The operation of each device in units CC ₀ , CC ₁ will now be described.

The arithmetic controller ACTL generates a timing signal in accordance with the instruction given together with the result of an logical operation, and controls the arithmetic device ARITH so that the necessary arithmetic operations are carried out therein. The system controller SCTL controls various operations in the unit CC ₀ , CC _x and controls the arithmetic controller ACTL. The peripheral controller PCTL controls the peripheral devices, such as the temporary storage devices TM, the magnetic drum channel devices MDCH, the speech path equipment SP , etc. The clock generator CLK generates clock pulses for triggering various types of flip-flop circuits of the central control unit CC. The EMA emergency facility only works during an emergency, as will be explained below. The manual test field displays the information signal given by the central control unit CC and the temporary memory TM and enables the operating status of the control unit CC to be changed manually.

2.1 Execution of an instruction

The execution of an instruction of the central control unit CC is described with reference to FIG.

A block FFG in the middle of FIG. 5 represents a group of controlling flip-flops which are suitable for reading and writing (that is to say not just for reading). The content of a register LR for storing the address of an instruction in the above group FFG is read out onto the operand rail PBB and + I is added by an adder ADD. The resulting signal goes via an intermediate register RBR and a result rail RBS into a memory register MAR. The read instruction for the temporary memory TM goes; there from the register MAR, controlled by the peripheral control ! 'CTL, via a Spcichcracircsscn / wischcnrcgisici- ^S 5 ADR and memory address lineeii MAI.

The response signal of the tempoi aicti Spi kIk-is / U eiimcleitcl by uliifr- AuslesiuislnikMu μ ι ι an intermediate memory register MBR via memory response lines MWL and the parity of the signal is checked by a parity circuit PTY. The signal then arrives in an instruction register IR and is treated as an instruction signal. If the parity circuit PTY detects a parity error, the bit “1” is set in an interrupt source register ISF in the group FFG .

The content of the instruction register IR is decoded by a decoder DEC and the type of instruction is determined. If a modification of the address is required, the Addieret ADD is controlled by the controller ACTL so that fra adder ADD performs an address modification. The modified address then goes to the memory address register MAR. If the decoder DEC detects an abnormal instruction code, the bit "1" is set in the interrupt source register ISF .

In the case of an instruction to read out data from the temporary memory TM , this instruction is given to the memory TM under the control of the peripheral controller PCTL as described above, and the data are read out into the intermediate memory register MBR via the memory response lines MWL.

When there is an instruction to input data into the temporary memory TM , the contents of the designated registers A ₀ , A ₁ , A ₂ , R _{3 are} set in the memory buffer register MBR via the adder ADD and the intermediate register RBR. A parity bit is added to the signal by the parity circuit PTY and the write instruction, under the control of the peripheral control PCTL, goes to the temporary memory TAi via memory data lines MDL.

In the case of an arithmetic instruction, the content of one of the registers R _n , A ₁ , R ₁ , R ₃ , identified by the instruction and / or the data readout in the readout method described above, goes to the adder ADD or a shift circuit SFT, via the operand rails PBA and PBB . The signal is processed by suitable logic operation, ie added or subtracted, or the signal is shifted on by the circuit SFT. The result is placed in a register defined by the instruction or a previously determined register. The result of the logic operation is checked by a result detector DET to determine whether it is positive, negative, equal to zero, and so on. The information derived therefrom is used to set a status code flip-flop (not shown), i.e. part of a register PSF for displaying the operating status of the group FFG .

In the case of a control instruction provided for the magnetic drum channel device MDCH , the instruction register IR sends CHOL to the device MDCH via channel operand lines. To transmit Sinti data between the magnetic drum units MDL , the address of the memory 7'Ai is combined via channel address lines CHAL to form an S; x 1-rather address intermediate register .. ABR . The data to be entered for the units MDU are stored on an intermediate memory register MBR via Kn!>. A! T! A! En! Ei! U !! ger! CHDL derived and the data read from di-ü linheilen MDlI via Kanalaiu w.irileituiigen CHWL / um register MHR gesan i! In I : \\ ι only, lie Spn v |] uvuesteueiimi> SPC l ·

In response to the relevant instruction, inspiration signals are passed from the instruction register IR and also from the register A ₀ via address lines SPAL to the controller 5PC, and the response from the controller 5PC arrives at an intermediate register BR via speech response lines SPWL.

2.2 Data adaptation

In normal operation, the two central control units CC ₀ , CC _x , controlled by a clock signal, execute an instruction synchronously, and at any point in time each of the units CC ₀ , CC _{1 contains} data which must be adapted to each instruction. The two units CC ₀ , CC ₁ exchange their data via the operand rails PBA, PBB whenever an instruction is executed, and the data are sent to the adder ADD via control lines MCTLL. The data are cross-checked for coincidence and direction. When the data of the units CC ₀ , CC ₁ are matched to one another, the units CC ₀ , CC ₁ carry out the instruction processing sequence. If there is no match, a corresponding bit is set in the interrupt source register ISF .

2.3 CC adaptation control Each of the control units CC ₀ , CC ₁ controls the other control unit CC ₀ , CC _{x in order} to maintain the functionality of the system. This type of control is referred to as »CC adaptation control« and is initiated by the SCTL control. The control signals are exchanged via control lines NCTLL.

2.4 Interruption

Interrupting measures are provided to interrupt the active instruction processing sequence and to initiate a new process. The previous process then continues. This action is referred to as "interruption" and the conditions for the interruption are stored in the interrupt source register ISF.

An interrupt mask function is provided for those cases in which an initiation of the interrupt process is not desired. The conditions for initiating this mask function are stored in a mask register IMF.

If interruption conditions exist, i. Ii. if the conditions match a source in the ISF register and not with one of the sources set in the IMF mask register, the contents of the LR registers, the PSF register and the ISF register are stored in a specific area of the temporary memory TM (not shown ) controlled by the system controller SCTL , and the register PSF and the register LR are set in a new pattern for control transfer to the interrupt program.

The program is returned to the interrupted program by resetting the registers LR, PSF and ISF with the data taken from the previous instruction.

2.5 Emergency operation

The EMA emergency facility is used to restore the functioning of the system if an error cannot be found due to a program change.

The following phenomena are considered to be a system failure and an emergency source detector

EMD detected, which starts the EMA emergency facility.

a) overflow of a timer for error detection in the control unit CC.

b) Power failure in the control unit CC or interruption of the clock pulse «.

c) Mismatch of the operating mode bits of the control units CC.

d) Overflow of an emergency timer (in the EMA facility) to count the time after

ίο release of the facility; EMA has passed.

After the emergency operation has been inserted, the various control circuits in the control unit CC are reset, controlled by the system control SCTL , the peripheral control PCTL, etc. The change in the operating status of the control unit CC is indicated by the part of the flip-flop group FFG . Then the change of the memory configuration, the start of the program loading for the temporary memory, or rather TM from the coin set drum unit MDV and the like, are carried out by the predetermined logic. The EMA emergency facility now successively establishes several effective combinations of units in the subsystem. The situation is known as an "emergency". A mixed register ^a 5 MISK stores every combination, ie every emergency cycle, of the EMA emergency facility. The emergency facility EMA modifies the initial program input from the magnetic drum unit MDU and then sets the bit "1" in the interrupt source register ISF so that the program continues. The beginning of each emergency cycle is recorded by a counter (not shown) in the EMA device. If a specified number of cycles is exceeded during a specified period, this is indicated in the mixed register MISK by a bit "1" and an alarm signal is given to the peripheral monitoring equipment (not shown).

2.6 Access control to the temporary memory TM The access control to the memory TM takes place according to FIG. 6 by a memory traffic control TRC in the peripheral control PCTL and by the system control SCTL. Access to the tempo

Rare memory TM from the central control unit CC only takes place in active operation. Access to a specific memory TM is decided by the three higher order bits of the memory address in the intermediate register ABR and by the in-

A replacement memory name register SNR, which is part of a display register SYF for the system status, is controlled by the memory record control TRC. A designator Y to indicate whether the control unit is in active or passive mode provided in the system status display register SYF . The designator Y is controlled by the system controller SCTL. Access takes place exclusively from a central control unit CC, which is in active operation. For example, access from the active unit CC ₀ in the temporary memory TM

<via the memory address lines MAL . The replacement memory name register SNR can also be part of the temporary memory TM . There is also accommodation for the substitute Spekhernamenregi sters in the central control unit CC and in the temporary memory TM possible. One of the registers SNR is in operation in this case.

Data to be stored in the memory TM go to practice

the memory data lines MDL ₀ . Responses from the memory TM in which the access took place are returned to the two control units CC ₀ , CC ₁ and to the intermediate memory register MBR via memory response lines MWL ₀ and MWL ₁ . The memory traffic controller TRC is used to combine the access requests from the control unit CC and from the peripheral equipment, such as the magnetic drum channel device MDCH or the like, since an access request from this peripheral equipment is also controlled by the peripheral controller PCTL.

2.7 Peripheral control

According to FIG. 6, the instruction from the central control unit CC to the peripheral equipment is only given by the active unit, denoted by the designator Y , via speech path address lines SPAL (FIG. 6) to the speech path control SPC .

2.8 Switching of the temporary memory TM Reference is made to FIG. 7 in this regard.

A number assigned to the storage devices TM ₀ to TM ₃ and ST-TM in relation to the central control units CC is defined in two ways. The first definition is a fixed number given to each unit by its physical connection in the hardware. The second definition is a logical device number by which the devices are logically identifiable. According to the program, the temporary memory TM is activated by the unit CC with the associated fixed facility number. The unit CC has access to the memory TM using the logic device number. The spare memory name register SNR is normally set to "111". In this case, all of the fixed device numbers are coincident with logic device numbers. In other words, this means that the central control unit CC normally has access to the temporary memory TM which has the fixed facility number designated by the program.

The content of the spare memory name register SNR can be set by the program. If the content of the register SNR differs from "111" , e.g. B. is "001", the logic device number of the temporary memory TM with its fixed device number "111" is set in the register SNR and the logic device number of the temporary memory TM with the fixed device number "001" is set to "111". If the access to the memory TM _{1 is designated} by a program, the unit CC has access to the facility ST-TM. As mentioned above, access is possible between the device ST-TM and one of the temporary storage devices of the memory TM. This is a particularly advantageous feature of the system.

2.M Control of the magnetic drum duct circulation

For this purpose, reference is made to FIG. H, in which solid lines denote the data paths and dashed lines denote the control paths. The magnetic drum channel device MDCH is controlled by the peripheral control PCTL . A central control unit CC _n , CC controls only a magnetic drum drum device MDCH, ie the unit CC _n controls the device MDCH _n and the unit CC ₁ controls the device MDCH ₁ . If data are to be read from the magnetic drum unit MDU ₀ , both the unit CC ₀ and CC _{1 give} instructions to the magnetic drum channel device MDCH ₀ . By the logic product of a channel designating signal in the instruction register IR and the signal in a designator X, which indicates the flip-flop of the Magneltrommelkanaleinrichtung MDCH, a signal is given only to the magnetic drum channel means MDCH ₀ via the control wire CHCTLA and the instruction from the unit CC reaches ₀ on the control wires CHCTLW only to the magnetic drum channel device MDCH ₀ .

The data read out are given to the temporary memory TM under the control of the peripheral control PCTL via the intermediate memory register MBR. If the unit CC _{0 is} supplied with a request for access to the memory TM from the magnetic drum channel device MDCH ₀ , then another unit CC _{1 is} blocked from accessing the memory TM until the unit CC _{0 has finished} its function. Response signals and information from the device _{MDCH 0} are returned to the two units CC ₀ , CC via the control line CHCTLW and cross lines between the two units CC ₀ , CC ₁ to these two units. the

^a 5 two units CC _n , CC, can thereby continue to control the devices MDCH _{0 synchronously.}

2.10 Magnetic drum control

According to FIG. 6, each magnetic drum system 0 and 1 consists of the magnetic drum channel device MDCH, which effects the transfer of information to the temporary memory TM , a peripheral magnetic drum device MDUE, which effects the selection of the tracks on the drum MDU , the supply of the control current for reading, the detection of the timing Track signal, the acquisition of the readout signal, etc., controlled by the device MDCH, and a magnetic drum mechanism MDUU with information tracks and a track selection matrix for these and a motor with its control circuit.

A clock signal is from a pattern on a

Clock track CLKT generated by the magnetic drum mechanism MDUU and detected by a clock detection sound TDET. The magnetic drum channel device MDCH causes the data to be read out or data to be transferred into the magnetic drum mechanism MDUU. The clock signal is sent to the central control unit CC in predetermined periods of e.g. B. 10 milliseconds via the code CHCTLW and is used to set a bit "1" in the interruption register ISF. This bit "1" in the ISF register causes an interruption in the CC unit.

The normal mode of operation of the magnetic drum duct device MDCH when reading in and reading out with the magnetic drum unit MDU is as follows. If a start instruction is sent from one of the central control units CC ₁₁ , CC ₁ to the corresponding magnetic drum channel device MDCH, then the instruction can be interpreted when the device MDCH is ready for operation. If the instruction requests data to be read in or out, the input / output control box (address of the Dalenlage to be transferred, address of the original data position, number of words in the transfer, etc.) is prepared beforehand in the temporary memory TM , from the memory TM transferred to a (not shown) control register in the channel device MDCH . The A-

MDCH direction also supplies a signal in response to the start instruction of the unit CC ₀ , CC _x by means of a state encoder CDC, not shown, which represents the operating state of the device MDCH. The response signal goes back via the control lines CHCTLW in the central control unit CC . After this introductory process, the operation of the device MDCH runs independently of the central control unit CC.

The device MDCH ensures the position of the objective data in the case of an input-output control command for reading out from the temporary memory TM . The device MDCH confirms the coincidence of the data situation and then transmits the following: Request for access to the memory TM for the peripheral control PCTL of the control unit CC ₀ , CC ₁ via the control lines CHCTLW. The data transfer then takes place controlled by the memory traffic controller TRC in the controller PCTL via the memory twist register MBR. This operation is repeated for each word. The device MDCH also serves to transfer the contents of the register LCR, which indicates the rotational position of the drum unit MD (J of the control unit CC . After the transfer is complete, a channel status word, which indicates the operating status of the magnetic drum system after the transfer has been completed, is transferred to a specified range temporary memory TM stored. A bit "1" is in the interrupt source register / SF via the control lines CHCTL W Act "/.um recording the operation completion to the control unit CC.

2.11 Temporary delay

The further explanation of the operation of the temporary memory is carried out on the basis of Fig. 6. The temporary memory TM is connected via individual lines to the respective central control units, CC, and, CC _1. The mode of operation of the memory TM begins when signal-characterizing information is controlled by the peripheral control PCTI. is supplied by one of the units CC _n , CC _1. An address identification signal is supplied by the central control unit CC, which sends the information identification signal to the memory TM , via one of the memory address lines MAL _n or MAL ₁ . The response signal on the memory T / V / goes back to the corresponding intermediate memory register MBR _n , MBR _S via the memory response lines MWL _n and _{MWL 1} .

In the name of a readout operation, the readout information is given in the temporary memory TM . When a read-in operation is identified, the information from the central control unit CC ₁₁ , CC ₁ , which has supplied the information designation signal, is given and stored in the temporary memory TM.

3. Intercom control and call detector

The speech equipment in this embodiment of the invention takes the form of a relatively small unit of mechanically locking crossbar switches with known network configurations for the speech paths. F.henso can be done by everyone Execution form of a switching network for distance spacing for voice control at the! fil ein »eset / l.

3.1 Speech control equipment

The speech path control equipment (SPC) comprises, as shown in Fig. 10, the switch controller SC and the typewriter control unit TPC , etc. in the peripheral control frame SPCF. The aforementioned switching function RYBIC or the standby measure n - \ - 1 can be used to improve the reliability of the equipment at a low cost

ίο be.

The decoding address information for controlling the speech path equipment is isolated from the central control unit CC so that the latter becomes simpler. In FIG. 10, SDD denotes a signal decoder .jnd distribution device and T1M denotes a control clock pulse distribution device. The combination of the two devices SDD and TIM is called a signal receiver and distributor SRD . In FIG. 10, MSCN is also the maintenance or maintenance interrogator, SC the switching control, RC the Rclais control. SCNDV the query driver and TPC the typewriter control.

The signal receiver and distributor SRD receives the information for controlling the speech path equipment

»5 genes from the central control unit CC and distributes the information to the corresponding facilities. In particular, the signal decoding and distribution device 5DD and the control clock pulse distribution device TlM, which is started by the device SDD and generates clock pulses, interact so that the information is exchanged between the signal receiver and distributor SRD and the central control unit CC . The information can be exchanged directly with the omission of an intermediate register. The clock pulses can be generated by a common generator.

The switch control SC consists of a hold control register SCR and a switch control driver SCDV. The switching control register SCR sets the signal information for the designated magnets of the respective mechanical crossbar switches, determined by a signal from the device SDD and the clock pulse derived from the device TIM. The switch control device SCD ^ controls the operation and the release of one or more switches using the above-mentioned SeIzsignals to define a requested speech path. The switching control .VC is further subdivided according to its mode of operation, the control.S'CZ, the switching unit LLS, the control SC-T, the switching unit TLS and the control .S'C-.STc a spare device that replaces the switching control SC -L or .VC-Takes part if these facilities should fail. With very little traffic, you can move to the SC-ST replacement unit and arrange a switching function R YIi / C between the Sehall controls SC-L and SC-T.

The relay control RC consists of a relay control register RCR and a relay driver RCDV. The relay control register RCR sets the information for the designated relays in the connecting line system according to a signal that is sent from the signal decoding and distribution device Sl) D and from ilen clock pulses from the execution TIM to determine the operational sequence of the Relay was derived. The relay driver RCDV controls the operation and release of the designated relays through the above signal. The double construction of the Hinrichluimcn RCR

and RCDV results in a substitute arrangement ÄC, and an active arrangement AC ₀ .

The interrogation driver SCND V causes a driver signal to select a row in the decoding matrix of the interrogator SCN, controlled by a signal which is derived from the signal decoding and distribution device SDD and is also duplicated.

The maintenance inquirer MSCN monitors the operational status of each device in the speech path control equipment (SPC). A signal distributor SD is used to distribute the signal for high speed sarity to the required parts in the voice control equipment (SPC). This initiates processes such as releasing the relays to switch over from an active device to the replacement device assigned to the trains, and the designation of the operating mode for the switching control SC or the relay control RC. The Typewriter Control TPC is used for manual communication with the system for maintenance purposes. 2 »

The equipment (SPC) works as follows. A speech path control signal is given from the central control unit CC to the signal decoding and distribution device SDD . The SDD device checks the received signal for errors. If the signal «5 is OK, it is decoded for the facility designation. The signal decoding and distribution device SDD now selects the designated switching controls SC, the relay control RC, the signal distributor SD, the scanning driver SCNDV , etc. using the decoded information. At the same time, the device SDD transmits the designated information received from the central control unit CC to the selected devices. For example, the driver information for the shift controller 5C-L is obtained from the central control unit CC . The signal decoding and distribution device SDD decodes the number or position of the element of the switch control SC-L and the driver information is set in the switch control register SCR of the control 5C-L. At the same time, the device SDD controls the clock pulse distribution device TIM so that a clock control of the switching control 5C-L can be effected by the clock pulses. The relay control RC is actuated in the same way, so that, under the control of the relay control RC, the designated magnet of the designated switch or relay can be actuated.

3.2 Rüfdelektor

The Rufdctcktor CD of FIG. ¹ J identified calling subscriber and generates a code which is housed in the interrogator 5CW. A control line of the relay controller RC is connected to the ring detector CD, so that the detector CD is riickstellbar this Sleucrlcitung.

The Rufdeteklor Cl) comprises a diode matrix I) M. Relay sounding DX, DYymt detection, Pi ioriialsfolgesignaloren PX, PY, a monitoring ^{circuit C -} AC and a code converter CWK L is a dividing relay, and CO are Rcluisahschaltkontakte.

In this system, the monitoring points for a large number of participants are divided into several groups. An element is provided for each Hlock (Rufde- leklors C1 ). The individual points of a Mloeks are in a matrix corresponding to the diode matrix I) M anizeonliiil. The diode matrix / 'Λ / is a matrix with 16 rows and 16 columns, with their crossing points consisting of a series connection of a diode and a contact 1 of the subscriber line relay L. The code converter CNVdienl for converting the information relating to the selected relays X and V into binary-coded information.

If a subscriber accommodated in the call detector CD picks up the receiver or handset or causes the "receiver off- hook" state in some other way, the relays X and Y in the detection relay circuits DX, DY and the Reiais XK, YK in the monitoring circuit CK respond and on Service request signal SR is sent to the interrogator SCN via a line SR and via contacts xk and yk. The service request signal informs the interrogator SCN that at least one subscriber belonging to the respective block is calling. The call conditions of a number of subscribers of a block are in this way iib-'r; the only line SR to the interrogator 5CV geszrcd '. At the same time, the number assigned to the subscriber is given into the diode matrix DM by actuating relay contacts in the detection relay circuits DX, DY. This information is transmitted to the interrogator SCN after code conversion in the coae converter CNV. The interrogator 5CN detects the information signal, whereupon the central control unit CC (FIG. 1) is supplied with the information pertaining to the number of the subscriber. The central control unit CC then establishes a connection between the calling subscriber and a corresponding register connection set ORT.

This process will now be described in more detail. If none of the subscribers assigned to the call detector (CD) call, ie the "handset hung up" status, all contacts 1 in the diode matrix DM are open, so that none of the relays A 'or V in the detection relay circuits DX, DY responds and thus no information on the Inquirer 5CV arrived. Now, when a subscriber, such as the lifts off the contact I ₀₀₀ associated subscriber, his handset speaks the relay A ",,,, in the detection relay circuit via a via this contact I ₀₀₀ extending circuit. The operation of Relay A ^ ₁₀ causes the Response of a relay XK in the monitoring circuit, which confirms that only one relay is working in the circuit DX . The relay XK holds the relay X ₀₀ and feeds the relay K ₀₁₁ in the detection relay circuit DY via a circuit not shown in detail K ₀₀ , a relay YK in the monitoring circuit CK is actuated after it has again been established that only one relay in the circuit DY responds. The relay YK holds the relay Y _n ., And sends a service continuation signal to the interrogator 5CW via the line SR information relating to the number of the subscriber in the diode matrix DM from the code converter CNV as a binary coded signal to the interrogator 5CW gesa ndt. If a lingering subscriber picks up the receiver, the circuits in the registration circuits I) X and / JK which are supplied for the corresponding Rcl'iis X and Y are switched off by the contacts X ₀₀ and V "" of the corresponding relays X _m and V ₁₁₀ so that these relays X, K cannot work at the same time and the information sent to the interrogator .STW and relating to the leil nehliK'i: tl! o! i iiiil'.l! »- ■■ iulrnchfuii

will. The central control unit CC processes the desired call connection after querying the service request signal SR and the output information from the code converter CNV. both housed in the .SCW interrogator. After the completeness of the call connection has been confirmed, a recovery signal is sent from the relay control ffC to the call detector CD . The call detector CD responds to the recovery signal by actuating a relay D / 5. The relay DlS switches off the actuation circuit of the relays -Y ₀ ,, and V ₀₀ in the detection relay circuits DX and DY and the re-initiation control RC confirms the restoration or resetting of the two relays X ₀₀ . V _0n and then also resets the relay DlS, as a result of which the call detector CD is again in its initial state.

After restoring or resetting to the initial state, the detector CD starts again

Ulli uci Ruici TaSaUiIg liZw. biciui ii'i diC-SciVi ZüSiäiki

until the next call comes in.

4. Overview of a voice connection

The control of the system for speech connections is defined by a program sequence stored in the memory. In contrast to ^J 5 conventional electromechanical switching systems, the system cannot be operated by the hardware alone. The system leads! Vermittlungsfunktinnrn i.ip'er use of service functions defining software through. The manner in which the system works in this regard is explained with reference to FIG.

11 shows a call monitoring state 1 in which the interrogator SCN determines the call condition of a subscriber by interrogating the line SR , which forwards the service request signal from the call detector CD to the interrogator .SCyV. It should be remembered that the call detector CD uses the matrix DM with 16 rows and 16 columns, i.e. for 256 subscriber lines in a block, when a subscriber in the block requests a call connection. the call detector CD gives a service request signal via the line SR to the interrogator SCN. The central control unit CC detects this request as a function of the result of the query on the line SR. If no service request signal is detected on the line SR , the central control unit CC reactivates the search for a service request during the next 200 milliseconds. If a service request is recorded, the central control unit CC identifies the number of the subscriber on the switching unit! LLS, depending on the information from the interrogator SCN, and then reads out the class of the calling subscriber from the magnetic drum unit MDU . The class of the calling subscriber is stored as information indicating whether this subscriber has a main line or a shared line or is calling from a public telephone box. Further information, for example the type of telephone set, whether it is a rotary dial or a touch-tone dialing set, or whether the subscriber is prevented from making the call. can be saved.

Depending on the class of the subscriber, the central control unit CC then selects a free corresponding connection set ORT from a plurality of connection sets receiving dialing impulses and establishes the connection of the calling party, as state 2 in FIG. 11 shows. In the normal crossbar telephone exchange system, the speech path connection between a calling subscriber and the corresponding register connection set ORT is made using a further third line, known as the "C line". As a result of the high speed of sound of the central control unit CC , the normal connection is unsuitable. In the present exemplary embodiment, the information relating to the available connection sets, chains or links is stored in a buffer area of temporary memory TM as a "card".

The central control unit CC refers / um required time on this information and causes the optimal way or Verbindtiiigssnl / .siichc After complete Vcrbindungsleitungssatzsuche the / enl rale control unit CC gibi the Vcrbindungsbefeh / in sound controller SC and to control a relay R (and the compound zwischrr the calling! eil iiciiuici and euispicdiendcii Regisieiveiiiiii Ground kit ORT is made. From this Regislerverbindungssatz ORT now reaches a Wählloi the calling party.

The central control unit CC monitors the operating status of this register connection set ORl aiie K) milliseconds via the interrogator SCN and detects the number or number dialed by the subscriber. This information is stored in an intermediate memory 'CB , which is present in the memory TM and is not shown in FIG. After completion of the counting and storage of all digits of the dialed number, the 2rn: r-le control unit CC reads out the data stored on the magnetic drum unit MDU and decodes the information relating to the called subscriber. This information can, for example, indicate whether it is an internal subscriber or whether the called subscriber's set is already busy! is. The control unit CC now forms connections according to state 3 in FIG. 11 and selects a free ringing connection set RBT which transmits the ringing tone to the calling subscriber, a free ringing connection set RGT. which transmits a ringing tone to the called subscriber, and a free internal connection set / OT for the called subscriber's answer. The control unit CC also effects a link search between the calling subscriber (SUBA), the connection set 1OT and the connection set RBT and between the called subscriber (SUBB) and the prevention set R (JT, based on the aforementioned .vartenlnformation in the temporary memory TM, which the For a fast voice connection when the called subscriber answers (SUBB) , a free link between the called subscriber and the connection set 1OT is selected and reserved for the subsequent voice connection. To transition from state 2 to state 3 in FIG central control unit CC give connection commands to the switch controller SC and the relay controller RC These processes are analogous to the connection of the calling party, as described in state 2.

During the connection of the called party, the operating status of the connection units RG1 and 10T is monitored at certain time intervals by the interrogator SCN , which receives the response of the other

called party or the interruption of the call by the calling party. If the called party answers, the reserved voice connection between the in-call subscriber (SUBB) and the connection seat 10T is now established and the speech path between the connection sets K) T and RIf] 'is interrupted, as shown in state 4 in FIG. 11. During the speaking connection, the Wc / cn · iral control unit CCaIIe issues a 100 millisecond query command to the interrogator .VCW and monitors the connection of the connection salt IC) T. The central control unit ( 'C stores the result of each query in the temporary Speieher TM and compares the result with animal preceding query is thereby a change is detected of the condition, so does the ¹ S unit CC indicates that the call has ended and it is the the following Unlcrbiechungsvorgang causes: ι) The envious participants put the receiver down? one after the other. In this case, all connections are immediately put on hold. b) Lvjjj! If a party does not pick up the handset immediately, the monitoring process continues and takes place after a certain, predetermined time if the handset is still not hung up. a forced break. ^a 5

5. How the program control works

It should be remembered that the memory of the system is formed by the temporary memory TM and the magnetic drum unit MDU . The temporary memory TM stores programs and data that are often used or the process requiring real time. The other program and data are accommodated in the magnetic drum unit MDU and, if necessary, transferred to the coverage area of the memory TM . The arrangement thereby forms a memory of hierarchical configuration.

The magnetic drum unit MDU is available twice and the temporary memory TM is only single. However, an arrangement is provided for using one of the units MDU as a replacement for the memory TM if it is defective. The temporary storage TM itself is constructed in such a way that a standby rope :! Iction ST-TM in place of one of the other arrangements 7M _1,. TM, TM ₂ , TM ₃ can occur.

The allocation of accommodation for the program and data in the memory TM and the unit MDU takes place in the following way for evaluating the redundancy features. The temporary storage devices TM _n to TM accommodate the program and data information which must always be present in the memory TM with regard to their use and the requirements of the real-time process. The programs that can be transferred from the unit MDU when a device of the memory TM is out of order are accommodated in the standby storage device ST-TM. All system program data, composed of all fixed and variable data with a lower access frequency, are accommodated in each of the double magnetic drum units MDU. For the storage devices TM ₀ to 7 "Af ₃ , coverage areas are provided for receiving program and data information, which is accommodated in the magnetic drum unit MDU.

5.1 Explanation of the programs

The system program includes the execution control program, the call processing program and the debug program.

The execution control program is a group of main programs for controlling the execution of various other programs, e.g. H. the call processing program and the error correction program. the interrupt control program, the feeling level control program, the planning control program and the magnetic drum control program. The execution control program is controlled by setting or resetting of the mask controller IMF, consisting of flip-flop sounds to prevent interruptions in the unit CC.

In the call processing program is eint · firiinnr from Programs for controlling the connection of a call from start to finish. The reputation distribution program itself consists of three programs, ti. left Incoming program, internal program and output program. The input program is a group of programs for acquiring the monitoring signal, of the selection signal etc. for subscribers and trunk lines etc. and for the delivery of a Requirement of a specified procedure for the internal processing program. The inner program is a group of programs for selecting the appropriate subscriber lines, connecting lines or Sprcchwcgc depending on the request from the input processing program and to provide an instruction for the output processing program. The output program forms a speech path or an interruption thereof or outputs a monitoring signal selection signal etc. according to the instructed command from the internal processing program.

The input or output program requires a periodic execution in real time functions of the monitoring signal or the selection signal or the operating configuration of the switching control SC and the relay control RC. Accordingly, these programs get a higher class execution level by interrupting less compelling real-time operations. For example, the internal program can be interrupted at intervals of H) milliseconds by rotating the magnetic drum unit MDU. The input program and output program are therefore called the clock program, while the inner program, which can be interrupted by the clock program, is called the low level program.

The debugger is a group of programs, generally when one occurs initiated by the fault detected by the circuit. The debugging program controls the identification the faulty setup! the restoration of the working capacity of the system and the renewed Start of the call processing program. There are several types of debugger for each cause of interruption. This program receives a higher implementation level Order than the clock level programs.

5.2 Accommodation of programs and data
in memory TM

In the illustrated embodiment of the Sv-

stems, in which only a small number of participants is to be accommodated, the temporary storage TM can consist of a single storage device TM _n and a standby device ST-TM . As the number of participants increases, the facilities TM _x , TM ₁ , TMy are added one after the other. The assignment of the program and data to the memory TM is carried out so that two devices (TM _n , TM ₁ ) are used. The execution control program, the error elimination program and the associated programs are assigned to the device TM ₁₁ . The standby device ΛΤ- TM are assigned programs with strict requirements for real-time and periodic execution. The magnetic drum unit MDU is a slow, periodic storage device in which programs are stored which are to be used in the event of a failure of the storage device TM ₁₁ . ie in the case of a replacement helicopter. in the case of | uem from the unit MI) U can be transferred to the device ST TM . Programs that can be carried out without reducing the processing capacity can be assigned to the ST-TM facility at uem. In the device TM _{n there} is a coverage area for transferring the basic level program in the unit MDU and a coverage area for receiving a clock level program in the unit MDL1 in the event that a device in the memory TM operates incorrectly. When the devices TM ₁ , TM ₁ , TM are added , the data accommodated in the device TM _n can be increased as the number of subscribers increases, and the data accommodated in the unit MDU can be correspondingly reduced.

5.3 Program processing

As already mentioned, in the present system the processing program changes if a defective device is present in the temporary memory TM. If the memory TM is working normally, the type of program processing is also normal. If an error occurs in the memory TM , the Vi ν irbciluiig takes place in substitute operation. These operating modes are described in more detail below.

a) Normal operation

The program processing in normal operation is! shown schematically in FIG. The symbols INI. CU Hl.C, MDCS denote the execution control programs, where INT is an interrupt program, CLC is a clock level control program, BLC is a basic level control program and MDCS is a magnetic drum control program. CLP is a clock level program, BLP is a basic level program, FP is an error recovery program, INB is the input buffer and OUB is the output buffer. Thin lines between the blocks indicate the path of the control program and thick double lines the flow of data. MDU _n , MDU ₁ are double magnetic drum units. Fig. 13 shows the sequence of operations in normal operation with time as the abscissa. The thick line on the axis CLP in Fig. 13 denotes the clock level programs which execute this clock level program, and the thick line on the axis BLP denotes! the basic level program and the execution of the basic level program. The dickei. Lines; on the axes MDU ,,. MDU represent the mode of operation of the magnetic drum unit MDU , starting from the time the device MDCH is initiated by the central control unit CC to the time when the complete program and data transfer between the memory TM and the unit MDU or vice versa. Also shown are the readout R from the unit MDU, the read-in or input W into the unit MDU and the clock interruption period T (K) milliseconds).

As already mentioned in connection with FIG. 5, in the event of an interruption, a corresponding bit is set in the interruption source register ISF . If the corresponding bit is not set in the IMF mask register that prevents the interruption, the

• 5 program INT according to FIG. 12, controlled by the system controller SCTL, initiated. The interrupt program reads the interrupt source register ISF and decides the execution level at which the interrupt source is heard. When dit.

jo interruption occurs during the execution of the basic level program BLP , the clock level control program CLC. controlled by the interrupt program INT, started, and the program CLC renews the clock memory in the temporary TM.

> 5 This clock memory is used exclusively by tlei group of the clock level programs CLP in the device ST-TM . A group of programs to be executed is started one after the other by the clock memory. After all programs have been completed, control is returned to the interrupt program INT . The program INT leads to the recovery of the interrupted information and for the control back to the interrupted program. While the program INT is working, the clock level program CLP is instructed to interrogate the connection set TRK, the call detector CD and various other devices by means of the interrogator 5CW, to check the existence of a call that requires internal processing.

* or other. When a call requiring internal processing is detected, one of the memories of the device INB is selected and the request relating to the information is written into the memory of the device INB. This memory is then registered in a long line waiting for internal processing. A memory in the output intermediate memory device OUB, prepared in the basic level program BLP and waiting in the long row for output processing, is selected and gives commands to the switching control .VC, the relay control RC and the signal distribution .SO, in the specified order. The basic level control program BLC picks up the memory of the device INB , requests the internal processing from the long line and addresses a conversion table for setting the stored address of the program BLP in the unit MDU and starts the magnetic drum control program MDCS.

The magnetic drum control program MDCS delivers commands for the magnetic drum channel device MDCH, based on the address in the unit MDU, and determines the start address for the transfer to the coverage area of the memory TM, given by the base level control program BLC . To prevent the transfer of

ίΠ IS LJ VVlIU CIIt

iiliuilllilllllll dun UtI llt'lillIIV-ll-ltlll corresponding bit is set in a mask register IMF

2N

Interrupt source cnrcgistcr ISF is set and the program expects the complete transfer.

In FIG. 3, the dashed line on the axis BLP of the basic level program indicates the monitoring of the transfer completion for the information from the magnetic drum unit MDU by the magnetic drum control program MDCS . The MDCS program returns control to the base level control program in the BLC once the transfer is complete. The basic level control program BLC then starts the basic level program BLP which was transferred into the coverage area of the memory TM . The program BPL analyzes the monitoring and identification signals, etc., based on the information in the above-mentioned input buffer device INB, and selects the connection set, switches and the like. If control of the peripheral system is required, the program BLP selects a free memory in the initial buffer device OUB and sets a control command in this memory which, registered in a long row, awaits the output processing.

If it is necessary to input or fetch data into the unit MDU at this stage, the magnetic drum control program MDCS is started. The program MDCS carries out a sequential control process in the manner described for the transfer of data between the unit MDU and returns control to the base level program BLP after the transfer has ended.

The internal processing programs that relate to the memory of the input buffer storage device INB are accommodated in the unit MDU as several overlapping areas, since the need for storage capacity varies with the processing required and overlapping areas should be as small as possible for reasons of economy. Therefore, if the data transmitted under the control of the basic level control program BLC exceeds the capacity of a single coverage area, the program issues a request for the MDCS program to route data to another coverage area. The program MDCS delivers a command based on the address of the next coverage area of the unit MDU and other information given by the base level program BLP and controls the transfer to the new coverage area in the manner described above. After the transfer is complete, the MDCS program starts the basic level program BLP.

The reading of the program and data from the magnetic drum unit MDU is effected by one of the double units Af DI ' ₀ or MDU ₁ . In particular, if there is no error in any of the double magnetic drum units MDU, in the magnetic drum channel devices MDCtI or in the central control units CC _n , CC ₁ , reading out from one of the units MDU _{n , KiDU 1} follows according to the program. If an error occurs, it is read out from the normal magnetic drum unit MDU. The input of data into the magnetic drum unit MDU takes place for both units MDU ₀ and MDU ,, so that the same information is recorded in each unit and this information in the event of failure b / tw. Defect of one of the recording systems is not lost

Each trunk unit MDU, .. MDU, and its assigned channel device MDCH _n , / WDCT /, is connected to the central control unit CC _{n assigned to it} . CC ₁ connected so that only the assigned central control unit CC can have access to the unit MDU _n , MDU ₁ . While the magnetic drum unit MDU is being controlled, a number assigned to the magnetic drum channel device MDCH is generated by the program, e.g. B. designated by an instruction. After this command has been executed, the number of the device and the content of the designator X ( FIG. 8) in the peripheral control PCTL are adapted. The device MDCH is then started by the assigned control unit CC _n , CC _t and the information / wipe the memory TM and the drum MDU

In this case, a signal indicating the completion of the transfer from the device MDCH is transmitted to each of the control units CC ₀ , CC ₁ , so that the operation of these units is synchronized.

After completion of an internal program relating to a specific memory of the input buffer storage device INB, the control is returned to the program BLC . The basic particle control program BLC now takes the next following

^a 5 gendcn memory of the device INB from the long line waiting for processing and effects the same processing as mentioned above. If there is no further memory of the INB device in the long row, the base level control program expects

3 «gramm BLC the registration of the facility INB from the clock level program CLP.

As mentioned above, with a larger number of participants, the capacity of the memory TM for accommodating a part of the internal program which was not originally accommodated in the drum unit MDU can be increased. In this case, the conversion table which indicates the address of the overlay program in the drum MDU and in a special device of the memory

* ° TM is housed, indicate that the program is now in memory TM and thus also the start address of such a program. The basic level control program BLC determines that the program is accommodated in the memory TM with reference to the conversion tables, so that the program in question can be started directly,
b) Substitute operation

The substitute operation takes place by transferring the clock level program CLP from the unit MDUm one

Coverage area of the memory TM if a device of the memory TM is defective. As mentioned briefly above, this mode of operation takes place by accommodating the clock package program CLP, which was previously in the standby device ST-TM in the normal

Operational was housed in the unit MDU. The clock level program CLP can be executed periodically, since the unit MDU has a periodic operating characteristic.

The minimum execution period T of the clock level program CLP has the following relationship to the rotation period τ of the unit MDU.

T = / tr,

where / 1 is an integer or its reciprocal. In the exemplary embodiment, T is equal to 10 milliseconds, r is equal to 20 milliseconds and therefore ;; same ' ,.

[); ix Takliu.'i>flnmi'r: imm CI P h <->;ii'ht .mc iin.i

21 40 7Q7

Number of individual programs. The implementation period of each of the programs should be an integral multiple of T. Assuming that the least common multiple of each execution period is mT (in the exemplary embodiment m = Kl and mn = 5) five tracks per unit MDL 'can be used to accommodate the entire clock level program CLP . In this case / i tracks (/ I = V ₂ ) contain the programs for a Takipcriode. The arrangement in the η tracks takes place in such a way that each program is distributed in each clock period, so that the following applies:

κ + tc% T,

where is is the maximum transfer time of the programs to be transferred in the clock period and te is the maximum execution time after the transfer (te = 4 milliseconds).

16 shows the accommodation of the individual programs of the clock level program CLP in one of the magnetic drum units MDIS ₀ , MDV _x . According to FIG. 16, individual program groups are CLPG1, CLPG1 ... CLPGW, each of which must be executed during each clock period. housed in a peripheral zone with a rotation time ts with an idle time te from the clock interruption P, to the start of each program. The execution of the program CLPGi, for example, transferred from the unit MDU into the coverage area of the temporary memory TM , is effected in a maximum time te after the occurrence of a clock interruption P _c. Immediately after completion of the execution of the program CLP for one clock period, the next program CLPGi + 1 is transferred, which must be executed in the following clock period to the unit MDU , so that when the next clock interruption occurs, the program CLPGi + 1 is already transferred and in the unit MDU is housed.

14 shows the substitute operation, with CLC-II being the clock level control program and AiDCS-II being the magnetic drum control program in substitute operation. These programs have a slightly different function than the corresponding programs in normal operation.

The main difference in the program processing in normal operation and in substitute operation is limited to the programs of the clock level control program CLC and the magnetic drum control program MDCH. In the backup mode, however, part of the magnetic drum unit MDU is used exclusively by the program CLP , and the writing of data to the magnetic drum MDU from the basic level program BLP is limited only to the part of the unit reserved for the program BLP .

Details of the programs CLC-II and MDGS-II are explained below. Since the other programs work like in normal operation, they are not explained in more detail.

Fig. 15 shows the sequence of operations. in substitute operation with time as the abscissa. The thick dashed line on the BLP axis for the basic level program represents part of the implementation of the MDCS-II magnetic drum control program. This part deviates from normal operation. However, other parts of the operation are the same as in normal operation according to FIGS. 13 and 14. In the exemplary embodiment, one of the magnetic drum units MDU serves as standby for the memory TM. The MDU units are divided into groups for the assignment of the CLP and BLP programs.

The clock level control program CLC-II will be

every clock interruption is started by the interrupt program INT and carries out the individual programs of the program CLP , which is transferred into the overlapping areas of the unit MDU , with the help of commands that are sent immediately after Ab

ίο conclusion of the previous program of the Taktpe gelpmgrammes CLP in the previous Taktpe node were derived. After completion of one of the programs · CLP , the control program CLC-II commands the transfer of the Pro

is grammgruppc (CLPG) in the following cycle, carried out by the AiDCS-II magnetic drum program. The AfDCS program for standard functions for monitoring the complete interruption and masks the transfer of voi

m> Data after submitting the transfer command to Magnet irornrneikanaieinheii MDCH. In contrast to this, the Frogramn MDCS-II does not form a mask after sending the transfer command to the MDCH device used for the CLP program

»5 returns immediately to the interrupt program INT and to the interrupted program via the control program CLC-U. As a result, the implementation of the base level program is even during the transmission time of the clock level program CLP

grammes BLP possible. The processing charge of the unit CC therefore does not differ significantly from that in normal operation, even at the time of the replacement of the unit MDU by the device ST-TM if an error occurs in the memory TM

occurs.

c) Working method for eliminating errors Measures for error detection are provided in the present system, although not in the Dctai shown, e.g. B. the mentioned circuit for adjustment

sen of the data between the units CC, the parity checking circuit of the memory TM and a detection circuit for illegal code. If an error is found, a corresponding bit is set in the interruption source register ISF , and dit

Fchlcruntcrbrcchung receives an h »> in the program feed through level as the clock break. The fan break interrupts the » Execution of the Rufpmgrammes and the control program and starts a faulty Trbcsciliguiigspro gram. depending on the source of the error break, via the interrupt program INT. The confirmation program causes the defective device to be identified, this device to be removed from the system and then renewed

Reputation warning.

When determining the faulty device in the unit MDU, the device MDCH or the Einheil CC, the system controller SCTL in the unit CC receives a command to stop the synchronous Bc iricbs of the units CC ₀ , CC ₁ , and the passive An order is separated from the active arrangement so that the system now only works with the active An order. If the faulty device is in the active arrangement, it is done quickly

6s exchange of active and passive arrangement through a command, and the connection is then terminated. If the system only works with the active An Order, this is how the cleaning program leads

the control returns to the program INT , which removes the interrupted information in the unit CC and the call processing starts again.

If the faulty device is found in the memory TM , the EMA emergency device is activated, since now the substitute operation mentioned must be used and it may be impossible to carry out the fault removal program. The EMA emergency device is started not only in the event of an error in the memory TM , but also in the event of an overflow of the program, the error detection time in the unit CC or an interruption in the power supply.

The device EMA links various combinations of memory 7 "Af and control ^{arrangement 1} S (CC, MDCH and MDU) _{1 in} order to find a usable combination. The device EMA first transmits the emergency program of the magnetic drum unit MDU to the memory TM and starts this program. The program attempts to provide a workable ^a0 combination of devices. When a part arbeilet the memory TM or of the units CC, MlJU or Einr.htungcn MDCH normal, they are zusanimcngcschaltet to form an emergency arrangement, which in normal operation and "5 in the replacement operation is working.

When an arrangement is made to work in normal operation or in substitute operation, the EMA emergency device sequentially selects emergency states according to the emergency program. Each of these states consists of a special combination of the devices TM ₀ IST-TM, CC _n , MDCH ₀ , MDU _0, ZCC ₀ , MDCH ₁ , MDU ₁ .

If the above emergency processing ensures that the system works in normal operation, the operation of the control units CC is synchronized again. If there is a defective device in a set of the devices CC, MDCH and MDU, the set of normal devices is made the active arrangement, the other arrangement is switched off, and the normal operating program is transferred from the unit MDU to the memory TM .

If only one mode of operation of the system in substitute operation is achieved, ie if one of the devices in the temporary memory TM is faulty, the replacement program is transferred to the memory TM . The ziigci <rdnctc logic number of the faulty device is set in the Frsr'i / spcicherregistcr SNR (Fig. 7). So

After each program is set in the memory TM , the call processing is resumed using the data relating to the call processing stored in the unit MDU , since the data relating to the call processing stored in the memory TM by the Execution of the emergency program can be destroyed. The data relating to a call are written into the unit MDU at the point in time when the called party answers or the conversation begins. As a result, when the call processing is resumed, a call which was already in the conversational stage when the error occurred is restored and a call. who had not yet reached this stage leads to the transmission of the busy signal to the calling party.

Debugging the peripheral control equipment can during the clock interrupt pcgcls or the base level without interruption of the call processing take place.

The peripheral control equipment, ie the device SRD, SC ₀ , SC ₁ , RC _x , SCN-DV, is arranged in such a way that errors can be detected by the emergency program. If the register SRD is faulty, the unit CC connected to the normal register SRD becomes an active arrangement and, if necessary, the previously active and passive arrangements are switched over. If no substitute device ST-SC is provided in the switching controls SC ₀ or SC ₁ , the mode of operation of the switching controller SC is changed so that the switching units LLS and TLS can be controlled by one of the controllers SC ₀ , SC ₁ . If a standby device ST-SC is available, the faulty switching control SC is switched off by the switching relays RYD and RYE. If an error is detected in the relay control AC ₀ or the. Query driver SCNDV ₀ , the restoration of the system is achieved by switching the relays RYA and RYF in such a way that the controller RC. or the driver SCND V _{x is used} in the system or vice versa.

6. Magnetic drum units

The access time (e.g. 10 milliseconds) to transfer programs and data from a single magnetic drum unit MDU can constitute a significant part of the system's operating time. Since this reduces the call processing capability of the system, it is in many cases unacceptable. It is therefore to choose the drum unit MDU that allows the shortest access time, which is described in the following.

18 shows the data output from the double magnetic drum units MDU ₀ , MDU _x . Each of the drums MDU ₀ , MDU ₁ has η tracks with 8 words per track and rotates in the period TD. Associated addresses in both units MDU ₀ , MDU _x are used to accommodate identical data. In Fig. 18, one abscissa represents Tdic time and the other abscissa WADR represents the data address of each unit. The data of one track is denoted as D, F, G, ... H, I, E. Each address circulates through successive stages 0 to 7. The address T ₀ - T _n . Represents information on η tracks of the corresponding magnetic drum units MDU ₀ , MDU ₁ .

It is assumed that the data D is to be accessed with the track address 4 and the address ό in the track at time I ₁₁ . As shown in the figure, the derivation of the data from the unit MDU _{n takes place} more quickly, since the access line is considerably shorter. The mean access time can be calculated as briefly indicated below. If both magnetic drum units MDU _n , MDU _{1 have} any variable phase position, the mean access time is V ₃ TD. If the data phases of the units MDU _U , MDU ₁ differ by V ₂ TD, the average access time is V ₄ TD. In any case, a considerable saving in access time is possible compared to the additional plan in which access to a single unit takes place with _{a central access line of V 2 TD.}

According to FIG. 8, the position of the detachment heads of the magnetic drum units MDU _n , MDU _x enables the following assignment to be determined:

The access time using the units MDU _n

= Head position of the MDU ₀ unit on the track at the moment

- Position of the top word of the content of the data to be read from the track and the like.

The access time using the unit MDU _x

= Head position of the unit MD U _x on the track at the moment

- Position of the top word of the content of the data to be read from the track.

This data can be used to decide which unit enables faster access; the index of the head on the current track can be read, and then processing goes according to the program Further.

Fig. 17 is a schematic representation of the preferred magnetic drum arrangement, blocks MDU ₀ and MDU ₁ denoting the aforementioned magnetic drum units in dashed lines. Since both units idDU ₀ and MDU _{x have the} same design, only the unit MDU _{0 is} shown and described in detail.

The magnetic drum channel devices MDCH and the magnetic drum units MDU are generally connected as shown in FIG. 19 so that the devices MDCH can effect a reading command for the transfer of data from the unit MDU , which enables the shortest access time and the writing of an instruction in a designated unit MDU ₀ , MDU ₁ .

The unit MDU ₀ has a magnetic drum MD with tracks T ₀ to T ₁₀₂ , with 2048 words of 16 bits each being stored per track. The track T _m produces a characteristic inv pulse per rotation of the drum AiD. A track T _c causes clock pulses to indicate the storage position of the information bits. H _n to H _i023 , H _m , H _e are magnetic heads corresponding to tracks T ₀ to T ₁₀₂₁ , T _n , T _c . The heads H ₀ to H ₁₀₂₁ are connected to a matrix MAT for selecting a head from the group of heads. A read signal for the selected head is connected in a demodulator device A to the matrix MAT , dc-modulated, and the result read in the form of a series of digital pulses appears on the line 101.

The signals read by the heads H ₁ and H _m are also converted into a series of digital signals via further associated demodulation devices A. The exit of the head H ₁ serve! / mn \ nitie! · a binary / deactivation CTR for 15 bits. The output of the head H _n serves to reset the counter circuit CTR, so that this circuit returns to "zero" once for each revolution of the drum MD. As mentioned, 204 words are used per track and 1h bits per word. With reference to the upper 11 bits of the counter CTR , it is therefore possible to obtain information about the world position in a track and, by means of the lower 4 bits, information about the image position in the read word.

The HADR block is a track address register for IO bits. The register HADR receives signals from the line ADR and then stores the upper IO bits in the word with 21 bits for the designation of the information, including all commands for the matrix MAT to select the required header. The block IAlUi is an address register in the track of II hits / in storage of the lower II bits of the above-mentioned word with 21 bits. The block COIN is a coincidence detection circuit which compares the content of the address register TADR and the upper 11 bits of the circuit CTR. Upon detection of coincidence by the circuit COIN , it generates an output signal on a line 102 to identify the word for which the instruction read is intended.

The output line 102 and a corresponding output line 103 of the unit MDU ₁ are connected to the inputs of a flip-flop circuit F, which operates as follows:

1. In the case of a pulse on line 102 at the same time as or before the pulse on the line

¹ signal 1021 generates the circuit fine signal »1«

on an output line 104.

2. In the case of a pulse on line 103 before that on line 102 , the circuit Fine generates signal "1" on an output line

*O 105.

3. With an impuis on a line κ, both lines 104 and 105 can be set to "0".

AND gates 106 and 107 can be triggered by signals on lines 104, 105 and allow the

^a 5 passage of a reading signal from the magnetic drum unit AfOiZ ₀ or MDU _x . A GDER gate 108 routes the output of both units MDU ₀ , MDU _x to a common output line DATA.

The operation of the magnetic drum units MDU ₀ , MDU _x will now be described. It is assumed that a reading instruction is given for a word with a track address zero and an address D in the track. In this case, the data address zero is given to the track address register HADR via the address line ADR , so that the matrix MAT selects the magnetic head H ₀ and the data address D is set in the address register TADR . When data D is on a track Vi ₀ as shown in FIG

♦ ° exist, the data in the unit _{MDU 0} can be read out earlier than those in the unit MD U ₁ , so that the output line 102 generates an output pulse earlier than the output line 103. Accordingly, the flip-flop circuit F generates a signal "0" on the Line 104 and the data at address D are passed through AND gate 106 and OR gate 108 to output line DATA . After the required word has been read, the flip-flop circuit F is reset to its idle state by a pulse on the line R. The reading process is finished.

By using this principle that the fastest line of access prevails, system efficiency is increased maximum. Without that shown in FIG

The order of selection is the mean access time K) milliseconds. With the selection arrangement according to Fig. 17, an average access time of n.7 is achieved Milliseconds.

7. Additional remarks

The invention has been described above for a telephone switching system. The discovery enables a number of other applications, such as data communication, for tele communication and in television telephone lines. The Spreehweg can go from two to four HrUhIe or on a mixed language wcuanordiiuiig mil two and four l.cilunucn modify! graze.

The main advantages of the system can be summarized as follows:

A. Normal operation

A4 program or data are transferred from the magnetic drum unit MDU to the temporary memory TM and carried out therefrom. The number of facilities in the temporary storage TM can therefore be reduced with a corresponding economy.

A.2 The coupling electronics between the peripheral equipment and the central control system carries binary-coded addresses and internal addresses of the equipment, since the distribution of Commands and responses from the peripheral equipment is centralized. This allows the Construction can be kept relatively simple.

A.3 By using the principle of selecting the magnetic drum with the fastest access time, the performance of the data processing can be increased considerably.

A.4 By synchronizing and adapting the mode of operation of the double central control units, greater reliability is achieved.

B. Occurrence of errors as B.l Occurs in one of the magnetic drum units MDU or the magnetic drum channel device MDCH in one of the double arrangements, then the input and readout takes place from the other arrangement. B.2 If one of the double central control units CC or the signal receiving and distribution units SRD show an error, then these double arrangements are separated, and the desired processing can be done by the normal arrangement.

B.3 If an error occurs in the temporary memory TM and the standby device ST-TM is not used normally, this device can take the place of the faulty device. However, if the replacement standby device ST-TM is used normally, then the replacement operation is applicable in which the magnetic drum unit MDU takes the place of the defective device in the memory TM . The storage system is therefore able to work even in the event of an error.

C. Call Detector

By using the call detector CD in the present system, the required capacity for the Rcalzciteingangsvcrarbcitungsprogramm can be reduced and thus also the number of temporary storage devices ( TM ₀ to TM ₃ ). Likewise, d.-.:-. Amount of input program information to be transferred from the magnetic drum fineness MDtI can be reduced. As a result, the call processing capacity in standby operation can be minimized.

D. Durc -: Use of the handset equipment

stung SfC , the load on the central control unit CC can be reduced. The transfer of the program and data from the Magnetic Control Unit MDU to the memory TM can thereby be done more conveniently, which enables the call processing capacity of the system to be maximized. The central control unit and the switching equipment can be easily separated, resulting in a simpler system construction.

In addition 13 sheets of drawings

Claims (16)

Patent claims: 1. Circuit arrangement for program-controlled telecommunications, in particular telephone switching systems, with several rewritable slow memories, input and output units connected to this slow memory, with several synchronously operating central control units for active and backup operation, each of these central control units being independent of one another is able to control input and output units belonging to its own group, at least two rewritable short-term memories shared by the central control units, some for active operation, some for backup operation, with each of the input and output units transferring information between the Jingsamen memories and the short-term memories due to causes a controller of the central control unit, and the central control unit causes processing of the data read out from the short-term memories, characterized in that only a small number With a few exceptions, there are active fast short-term memories (TM) that are connected to a double-managed, shared, but independently working replacement short-term memory (ST-TM) , and a correspondingly larger number of double-managed, slow memories (MDU) and double-managed ones Central control unit (CC) it is provided that each of the central control units (CC) contains a register (SNR) for recording the device number of one of the fast short-term memories, the content of the slow memories (MDU) being stored on these by a short-term memory (TM) and vice versa, the content of a short-term memory can be transferred to the slow memory (MDU) with the help of the register (SNR) for the logic addresses used for the input and output units (MDCH) and if one part or several different parts fail (short-term memory TM, replacement short-term memory ST -TM, slow storage MDU or central control unit CC) his or her task is carried out by another part that when storing a facility number of a short-term memory (e.g. B. 7 "M ₀ ), except for the replacement short-term memory (ST-TM), in the register (SNR) and if an access from the central control unit to the short-term memory (TM _n ), the device number of which is stored in the register (SNR) , is necessary, the access to the substitute short-term memory (ST-TM) takes place so that each central control unit (CC) only sends command information to the input and output units (MDCH) belonging to its own group, and that every input and output unit (MDCH) response signals and Information can only be returned to the two central control units (CC ') . 2. Circuit arrangement according to claim I, characterized in that ckiL! a single replacement Kurzzcitspcicher [ST-TM) is provided. 3. Circuit arrangement according to claim I. characterized in that el η B the register (SNIO in ilen /: r, lr; ili η MeiicremlicitCM (CC) is provided 4. Circuit arrangement according to claim 1, characterized in that the register (SNR) is provided in a device composed of the short-term memory (TM). 5. Circuit arrangement according to claim 1, characterized in that the register (SNR) is provided in the central control units (CC) and in one of the short-term memories (TM) = the unit. 6. Circuit arrangement according to claim 1, characterized by devices which ensure that the data are read from that slow memory (MDU) which offers the fastest access time. 7. Circuit arrangement according to one of the preceding claims, characterized a) through several slow memories (MDT '), b) by peripheral equipment with input-output processing devices, that are connected to the storage tanks, c) through several fast short-term memories (TM), d) by double-guided, central control units (CC) for synchronous operation with the fast memories (TM) and for controlling the input-output processing devices, e) through registers (SNR) which connect the short-term memories (TM) and the control units (CC) and serve to convert logic addresses for the central control units and addresses between the equipment and within each equipment, f) by means for controlling the units in such a way that a unit in the active mode and another working in passive mode, with one control unit for supplying the fast memory with address signals and for writing Data in this is used, and both central control units receive response signals from the record fast, temporary storage, and g) by means for feeding back the result of a program execution by the input-output processing means to the central control units (CC). 8. Circuit arrangement according to claim 7, characterized by a device for the transmission of information from the slow memories (MDU) to the fast short-term memories (TM). 9. Circuit arrangement according to claim 7, characterized by devices which ensure that the specific information to be accessed first is read out of the slow memory (MDU). 10. Circuit arrangement according to claim 7, characterized by a Rufdctcktor connected to the Teilnehnierleitungcn for detecting the outgoing call from a calling subscriber and for delivering coded information to the control units (CC), representing an assigned number or number of the respective subscriber. II circuit arrangement according to .spruch 7, dadurib! '. I-ktMinzeiciiiiet. d.ill die l, nu: - ,, imcn memory Ml)!) . ".. · _ ■ 1. 1 .. ^l > 1 liifomi i'ion sneich.-rn and that means for reading out information from the slow memories (MDU) for the desired transfer of information from the slow memories (MDU) into the fast memories (TM) and for accessing the fastest available information from the slow memories! (MDU) are provided. 12. Circuit arrangement according to claim 7, characterized in that means for continuous Comparison of data in the control units (CC) to determine non-equivalent Data are provided. 13. Circuit arrangement according to claim 7, characterized by signal receiving and distributing devices between the central control units (CC) and the processing devices and by devices for supplying clock pulses, the distribution device binary-coded information from the central control unit (CC), which is made from - ao armament addresses is composed _; and work commands for issuing intra-peripheral equipment addresses or commands according to the designated intra-peripheral equipment address in the form of clock pulses and the distribution device also receives response signals from the peripheral equipment and is used to deliver the response signals to the central control units (CC) . 14. Circuit arrangement according to claim 1, characterized by a program address conversion table stored in the slow memories (MD U). 15. Circuit arrangement according to one of the preceding claims, characterized in that devices are formed from the slow memories (MDU) and the fast memories (TM) and that measures are provided for transmitting data between slow and fast memories (MDU, TM). 16. Circuit arrangement according to one or more of the preceding claims, characterized by synchronizing and adapting the operation of the duplicate components of the control devices (CC) so that one Storage program for isolating a faulty component is created while the System by using the working components of the duplicated facilities is kept in operation.